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US10203403B2ActiveUtilityPatentIndex 56

Low-cost underwater acoustic system for real-time three-dimensional imaging

Assignee: LEONARDO SPAPriority: Feb 15, 2017Filed: Feb 15, 2017Granted: Feb 12, 2019
Est. expiryFeb 15, 2037(~10.6 yrs left)· nominal 20-yr term from priority
Inventors:FABRIZIO FERRAIOLIRENATO MARASCO
G01S 7/5273G01S 15/89G01S 7/52003
56
PatentIndex Score
5
Cited by
11
References
10
Claims

Abstract

Examples described herein include an acoustic system for the imaging of underwater objects, comprising an underwater transceiver antenna of electro-acoustic type, and control and processing means configured to carry out an imaging step.

Claims

exact text as granted — not AI-modified
The invention claimed is: 
     
       1. An acoustic system for the imaging of underwater objects, comprising an underwater transceiver antenna of electro-acoustic type, and control and processing means configured to carry out an imaging step including:
 transmitting, by means of the underwater transceiver antenna and for each azimuth angle included in a predetermined range of azimuth angles, a corresponding acoustic pulse by
 using a fan beam pointed at said azimuth angle and having a predetermined width in azimuth and a predetermined width in elevation, wherein said predetermined width in elevation is greater than said predetermined width in azimuth, and 
 feeding the underwater transceiver antenna with excitation signals such as to cause a coherent recombination of corresponding acoustic signals transmitted in water at a three-dimensional focusing region located at a predetermined focusing distance from the underwater transceiver antenna, at which predetermined focusing distance an underwater object is located; 
 
 
       wherein the acoustic pulses are transmitted by varying azimuth pointing of the fan beam so as to perform a complete scan of the predetermined range of azimuth angles;
 for each acoustic pulse transmitted, receiving a corresponding echo signal by means of the underwater transceiver antenna; 
 processing the received echo signals by performing a beamforming method so as to compute a three-dimensional digital map of powers associated with a predetermined grid of points located in the three-dimensional focusing region; wherein the received echo signals are processed by forming pencil beams, each of which is pointed at a corresponding point of said predetermined grid; and 
 processing the three-dimensional digital map of powers by performing an edge detection method so as to form an image of the underwater object. 
 
     
     
       2. The system of  claim 1 , wherein the control and processing means are configured to carry out the imaging step by feeding the underwater transceiver antenna with square-wave excitation signals having predetermined delays such as to cause a coherent recombination of corresponding acoustic signals transmitted in water at the three-dimensional focusing region. 
     
     
       3. The system according to  claim 1 , wherein the control and processing means are configured to carry out also a detection step including:
 operating the underwater transceiver antenna to transmit isotropic acoustic pulses and to receive corresponding echo signals; 
 computing average powers of samples of said echo signals by using a sliding window of integration of squared amplitudes of the samples of said echo signals; 
 weighting the computed average powers by an exponential function of compensation for spherical divergence attenuation; and 
 detecting an underwater object on the basis of the weighted average powers and of a detection threshold. 
 
     
     
       4. The system of  claim 3 , wherein the control and processing means are configured to carry out the detection step by feeding the underwater transceiver antenna with square-wave excitation signals. 
     
     
       5. The system according to  claim 3 , wherein the control and processing means are further configured to:
 compute a distance, from the underwater transceiver antenna, of an underwater object detected in the detection step; and 
 carry out the imaging step by using said computed distance as the predetermined focusing distance. 
 
     
     
       6. The system according to  claim 3 , wherein the underwater transceiver antenna comprises active electro-acoustic transducers and passive electro-acoustic transducers; and wherein the control and processing means are configured to carry out the detection step by operating:
 in transmission, active electro-acoustic transducers arranged in a central region of said underwater transceiver antenna; and 
 in reception, passive electro-acoustic transducers arranged in said central region of the underwater transceiver antenna. 
 
     
     
       7. The system according to  claim 1 , wherein the underwater transceiver antenna comprises:
 a transmitting antenna that includes two arrays of active electro-acoustic transducers lying on one and the same plane; and 
 a receiving antenna that includes five arrays of passive electro-acoustic transducers lying on said plane; 
 
       wherein:
 a first array of passive electro-acoustic transducers mainly extends along a first rectilinear direction lying on said plane; 
 the two arrays of active electro-acoustic transducers mainly extend along a second rectilinear direction that lies on said plane, is perpendicular to the first rectilinear direction and intersects said first rectilinear direction at a point identifying a phase centre of the underwater transceiver antenna; 
 the two arrays of active electro-acoustic transducers extend along the second rectilinear direction, each on a respective side with respect to the phase centre; 
 the first array of passive electro-acoustic transducers extends through the phase centre and on both sides with respect to said phase centre along the first rectilinear direction; 
 a second and a third array of passive electro-acoustic transducers mainly extend along a third rectilinear direction that lies on said plane, passes through the phase centre and is inclined by 45° with respect to both the first rectilinear direction and the second rectilinear direction; 
 the second and the third array of passive electro-acoustic transducers extend along the third rectilinear direction, each on a respective side with respect to the phase centre; 
 a fourth and a fifth array of passive electro-acoustic transducers mainly extend along a fourth rectilinear direction that lies on said plane, passes through the phase centre and is inclined by 45° with respect to both the first rectilinear direction and the second rectilinear direction and by 90° with respect to the third rectilinear direction; and 
 the fourth and the fifth array of passive electro-acoustic transducers extend along the fourth rectilinear direction, each on a respective side with respect to the phase centre. 
 
     
     
       8. The system of  claim 7 , wherein each of the two arrays of active electro-acoustic transducers includes respective active electro-acoustic transducers spaced apart from one another according to a first spacing law; and wherein each of the five arrays of passive electro-acoustic transducers includes respective passive electro-acoustic transducers spaced apart from one another according to a second spacing law. 
     
     
       9. The system of  claim 8 , wherein:
 in each of the two arrays of active electro-acoustic transducers, the spacing between the barycentres of adjacent active electro-acoustic transducers increases with increasing distance from the phase centre according to a first nonlinear law; and 
 in each of the five arrays of passive electro-acoustic transducers, the spacing between the barycentres of adjacent passive electro-acoustic transducers increases with increasing distance from the phase centre according to a second nonlinear law. 
 
     
     
       10. A non-transitory machine readable computer program product comprising software code portions that are:
 executable by electronic processing means of an underwater acoustic system comprising an underwater transceiver antenna; and 
 such as to cause, when executed, said electronic processing means to become configured as the control and processing means of the system claimed in  claim 1 .

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